CN106999719A - Method and apparatus for the particle advancing of contactless axial particle rotation and decoupling - Google Patents
Method and apparatus for the particle advancing of contactless axial particle rotation and decoupling Download PDFInfo
- Publication number
- CN106999719A CN106999719A CN201580059621.XA CN201580059621A CN106999719A CN 106999719 A CN106999719 A CN 106999719A CN 201580059621 A CN201580059621 A CN 201580059621A CN 106999719 A CN106999719 A CN 106999719A
- Authority
- CN
- China
- Prior art keywords
- particle
- magnetic
- rotation
- magnetic field
- gradient
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Granted
Links
Classifications
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01F—MAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
- H01F1/00—Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61N—ELECTROTHERAPY; MAGNETOTHERAPY; RADIATION THERAPY; ULTRASOUND THERAPY
- A61N1/00—Electrotherapy; Circuits therefor
- A61N1/40—Applying electric fields by inductive or capacitive coupling ; Applying radio-frequency signals
- A61N1/403—Applying electric fields by inductive or capacitive coupling ; Applying radio-frequency signals for thermotherapy, e.g. hyperthermia
- A61N1/406—Applying electric fields by inductive or capacitive coupling ; Applying radio-frequency signals for thermotherapy, e.g. hyperthermia using implantable thermoseeds or injected particles for localized hyperthermia
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B82—NANOTECHNOLOGY
- B82B—NANOSTRUCTURES FORMED BY MANIPULATION OF INDIVIDUAL ATOMS, MOLECULES, OR LIMITED COLLECTIONS OF ATOMS OR MOLECULES AS DISCRETE UNITS; MANUFACTURE OR TREATMENT THEREOF
- B82B3/00—Manufacture or treatment of nanostructures by manipulation of individual atoms or molecules, or limited collections of atoms or molecules as discrete units
- B82B3/0061—Methods for manipulating nanostructures
- B82B3/0066—Orienting nanostructures
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01F—MAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
- H01F13/00—Apparatus or processes for magnetising or demagnetising
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01F—MAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
- H01F7/00—Magnets
- H01F7/02—Permanent magnets [PM]
- H01F7/0273—Magnetic circuits with PM for magnetic field generation
- H01F7/0278—Magnetic circuits with PM for magnetic field generation for generating uniform fields, focusing, deflecting electrically charged particles
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01F—MAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
- H01F7/00—Magnets
- H01F7/06—Electromagnets; Actuators including electromagnets
- H01F7/20—Electromagnets; Actuators including electromagnets without armatures
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02N—ELECTRIC MACHINES NOT OTHERWISE PROVIDED FOR
- H02N15/00—Holding or levitation devices using magnetic attraction or repulsion, not otherwise provided for
Abstract
The apparatus and method manipulated for magnetic particle, it can cause particle independently rotation and translation using the magnetic field and magnetic field gradient produced, and the apparatus and method generate the translational motion and rotary motion of desired decoupling.Apparatus and method for manipulation can be implemented as while being related to many particles.Rotating excitation field for causing rotary motion can be altered to cause Particles Moving, and the Particles Moving is same phase or out-phase with rotating excitation field.Magnetic field described herein and magnetic field gradient can be produced by some combinations of permanent magnet, electromagnet or permanent magnet and electromagnet.
Description
Cross reference
It is entitled this application claims what is submitted on October 31, in 2014 according to United States Code No. 35 chapter 119 (e) money
“METHOD AND APPARATUS FOR NON-CONTACT AXIAL PARTICLE ROTATION AND DECOUPLED
PARTICLE PROPULSION " U.S. Provisional Patent Application No.62/073,360 (entire contents are incorporated by reference into)
Priority.
Technical field
Disclosed embodiment is related to the method and apparatus of manipulation magnetic particle.
The content of the invention
Disclosed embodiment, which is provided, is used for the apparatus and method that magnetic particle is manipulated, and it can utilize the magnetic produced
And magnetic field gradient cause particle independently rotation and translation, the apparatus and method generate desired decoupling translational motion and
Rotary motion.
Disclosed embodiment, which is realized, manipulates this particle having more than a magnetization direction.
Disclosed embodiment, which is provided, can be implemented as while being related to the device for being used to manipulate and the side of many particles
Method.
Disclosed embodiment provides the apparatus and method for being used for manipulating at least one particle, and it will be used to make particle
The magnetic field gradient of translation and the magnetic field combination for rotating at least one particle, this method are used for the translation for causing particle simultaneously
And rotation.
Disclosed embodiment provides and uses rotating excitation field, to cause rotary motion, wherein, rotating excitation field can be by
Change to cause Particles Moving, the Particles Moving is same phase or out-phase with rotating excitation field.
Disclosed embodiment is provided and used can be by the one of permanent magnet, electromagnet or permanent magnet and electromagnet
Combine a bit come the magnetic field produced and magnetic field gradient.
Brief description of the drawings
Specific description more particularly to the following drawings, wherein:
Fig. 1 to Fig. 4 shows wherein there is zero field gradient or insignificant field gradient (H by applyingRotate-zero-gradient) rotary magnetic
Field rotates the embodiment of manipulation to realize.
Fig. 5 to Fig. 6 shows the embodiment of usable particles with superparamagnetism, and the particles with superparamagnetism can be partially coated with
Ferromagnetism component, the ferromagnetism component is magnetized on the direction vertical with the long axis of particle.
Fig. 7 to Fig. 8 shows the embodiment according at least one, once magnetic field is removed, Fig. 5 shows into Fig. 6
How the intensity of magnetization of the superparamagnetism main body of the particle gone out will undergo nile (Neelian) relaxation (due in nano-particle
The change of the intrinsic intensity of magnetization and produce).
Fig. 9 to Figure 14 shows the configuration according to disclosed embodiment offer, with according at least one
The combination of revolving force and propulsive force is provided on one or more particles of embodiment.
Figure 15 shows the cylinder with magnetic sections of the embodiment according at least one, the length of the magnetic sections
Cylinder diameter of the degree more than twice, and the magnetic sections have the intensity of magnetization axis along the length of cylinder.
Figure 16 shows an example of the operation of the device according to disclosed embodiment offer.
Embodiment
Frequent reference to magnetic field needs succinct term index.
Magnetic field with insignificant gradient is referred to alternatively as HZero-gradient.If the magnetic field is rotation, it is referred to alternatively as
HRotate-zero-gradient.One example of the rotating field with zero gradient is as the field produced by such ac coil:The exchange is carried
Streamline circle rotates around any axis parallel with the face of the coil.By making ac wire be put down around with the face of the wire
Capable axis rotation, zero gradient magnetic field is produced in the center of the coil.
Magnetic field gradient is referred to alternatively as HWith-gradient.If the magnetic field gradient is rotation, it is referred to alternatively as HRotation has-gradient.Tool
The rotating excitation field for having gradient (that is, can make the bar magnet vertical around it by making long and narrow bar magnet be rotated around its minor axis
Long midpoint rotation) and produce.
Magnetic particle has associated magnetic field, and the magnetic field is similar with the magnetic field of common bar magnet.The magnetic field of particle can
It is referred to as HParticle。
Magnetic particle also has the intensity of magnetization.The intensity of magnetization of particle is the magnetic order for the magnetic domain for constituting the particle.Particle
The intensity of magnetization is referred to alternatively as MParticle。
Magnetic particle can have two different magnetic sections, wherein, each several part has the magnetization direction of their own.
In the case of multiple magnetisable sections on same particle, the section intensity of magnetization is referred to alternatively as M1, particleAnd M2, particle.In cylindrical particle
In the case of, M1, particleIt will refer to the intensity of magnetization along the long axis of cylinder, and M2, particleIt will refer to the major axis perpendicular to cylinder
The intensity of magnetization of line.
Disclosed embodiment is related to the method and apparatus of actuating magnetic particles, wherein, translational motion and rotary motion can
Decoupling, wherein, there is zero field gradient or insignificant field gradient (H by applyingRotate-zero-gradient) rotating excitation field come realize rotation behaviour
Control, and by applying the global magnetic field (H with ferromagnetic particlesParticle) parallel alignment or antiparallel alignment rotating excitation field gradient
(HRotation-there is-gradient) realize translational motion.Ferromagnetic particles (being similar to common bar magnet) have associated global magnetic field
(HParticle).Global magnetic field (the H of particleParticle) produced by the magnetic domain in particle.Any magnetic field gradient (HGradient) and it is overall
Particle magnetisation (MParticle) parallel alignment particle will be caused to be moved up in the side that gradient reduces, i.e. away from magnetic gradient
(HGradient) source movement.Magnetic field gradient (HGradient) and the integral particles intensity of magnetization (MParticle) antiparallel alignment will cause particle in ladder
The side of degree increase is moved up, i.e. moved towards the source of magnetic gradient.
According to disclosed embodiment, uniform rotation of the application with zero magnetic field gradient or insignificant magnetic field gradient is used as
Turn magnetic field (HRotate-zero-gradient) result, the ferromagnetic particles with the size between 100 microns and 10 nanometers can surround one axle
Line is rotated.
According to disclosed embodiment, the rotation of particle and magnetic field (HRotate-zero-gradient) rotation can for it is either in phase with one another or that
This out-phase.
According to disclosed embodiment, the composition of particle different can be loaded into the particle comprising many or be loaded into this
Material or object on particle.These materials or object may include medicine, protein, other particles, molecule or cell.The particle
Electronic unit is may also comprise, including:(such as glucose fires for capacitor, resistor, diode, transistor or energy gathering devices
Expect battery).Alternatively, disclosed embodiment, which can be used, can be partially coated with the particles with superparamagnetism of ferromagnetism component.
In the case where being coated with the superparamagnetism cylinder of ferromagnetism component, the ferromagnetism component can have the long axis with particle to hang down
Straight magnetic moment.
Disclosed embodiment can integrally be realized or partly realized, to realize the rotation of particle, closely be connect to produce
The bubble and/or vacuum (such as air pocket) of nearly particle, the bubble and/or vacuum be used for by magnetic resonance, ultrasonic wave or its
Make the particle imaging by increasing effective highlighting of particle during its known imaging technique observation, or for being justified by adjusting
The length of magnetic sections on cylinder particle obtains the vertical magnetization on single particle.On same particle, particle can have
There are multiple ferromagnetism sections or superparamagnetism section.These sections can be region different on magnetic force, mean them by diamagnetism
Material is separated, and their magnetic domain (M1, particleAnd M2, particle) it is independent of each other.Cross magnetization intensity on single particle is related to
And such particle:The particle has multiple magnetic sections, and (it produces M to the magnetic domain of the plurality of magnetic sections1, particleAnd M2, particle) produce that
This magnetic field existed into an angle of 90 degrees.
The contactless manipulation of particle can realize conventionally milled as magnetic field is applied to magnetizable particle, such as by
The periodical in June, 2005 such as D.L.Fan《Physical Review Letters》Volume 94, No. 247208 article, topic
For " (entire contents are by quoting for Controllable High-Speed Rotation of Nanowires " publication
And be incorporated herein) taught in.Early stage research on rotated millimetre level magnetic material and the theme of equipment has concentrated on
Chiral material, as K.Ishiyama etc. in 2001《Sensors and Actuators A》Volume 91,141-144
Their publication " Swimming micro-machine driven by magnetic the torque " (entire contents of page
Be incorporated by reference into herein) in it is contemplated.
Various papers have illustrated the micron order drill bit and nanoscale drill bit by rotating screw shape structure, such as by
Periodicals of Ambharish Ghosh and the Peer Fischer in 2009《Nano Letters》9th (6) volume, 2243-2245
Disclosed publication " the Controlled Propulsion of Artificial Magnetic Nanostructured of page
In 2013 years in Propellers " (entire contents are incorporated by reference into herein) and such as by Kathrin E.Peyer
Periodical《Chemistry A European Journal》Volume 19, the 28-38 pages of publication " Magnetic Helical
Taught in Micromachines " (entire contents are incorporated by reference into herein).
In the prior art, the rotation of spiral shape particle is by by uniform rotating excitation field (HRotate-zero-gradient) apply to the grain
Son is realized.In the case of micro- spiral shape equipment (Ghosh and Fischer (2009), Peyer etc. (2013)) mentioned above,
Magnetic field (HRotate-zero-gradient) be oriented on the direction orthogonal with the expection translation direction of particle.In addition, in the feelings of micro- spiral shape equipment
Under condition, the rotation of equipment causes the translation of equipment.
In addition, the periodical such as by Brandon H.McNaughton in 2006《Physical Chemistry B》The
100 (38) volume, the 18958-18964 pages of publication " Sudden Breakdown in Linear Response of a
Rotationally Driven Magnetic Microparticle and Application to Physical and
Instructed in Chemical Microsensing " (entire contents are incorporated by reference into herein):In rotating excitation field
(HRotate-zero-gradient) in magnetic particle will keep with the same phase in magnetic field, be not enough to strong be somebody's turn to do to driving until the magnetic particle is in magnetic field
At the point of the same phase rotation of particle.Drive the rotating excitation field (H of particle rotary motionRotate-zero-gradient) must pull against for protecting particle
Hold with rotating excitation field with the viscous drag power on the particle of phase.Because drag increases with the rotary speed of particle,
In the presence of some such frequencies:The rotating excitation field given with these frequencies becomes to be not enough to continue to drive particle and rotating excitation field same
The rotary motion of phase.
When the drag on particle become than it is big as the driving force produced by rotating excitation field when, particle rotational slide into drive
Moving field rotates out-phase.The boundary is referred to as " critical slip circle point ".The point for critical slip circle occur be due to following several factors and
Produce:Towing, rotation on particle are mainly applied to by the one (or more) kinds of fluids or one materials of surrounding
The intensity in magnetic field and the overall magnetic property of particle.
Due to considering the understanding for prior art, therefore disclosed embodiment causes particle with rotating excitation field in phase
Rotation out of phase rotates with rotating excitation field.The rotation of particle and rotating excitation field out-phase can be controlled by applying rotating excitation field.
First application such as the particle by the magnetically actuated instructed such as Ghosh etc. and Peyer employs spiral winding, according to
The coupling of translational motion and rotary motion is promoted by the spiral winding.On the contrary, embodiment disclosed in this invention is provided
The method and apparatus of actuating magnetic particles, wherein, translational motion and rotary motion are decouplings.
In the disclosure, it should be understood that geometry described herein and vocabulary used herein are for this
Invention is specific.For example, phrase " long axis " and " minor axis " refer to the axial axis and longitudinal axis of cylinder respectively.It is long
The center of two substrates of axis connecting cylinder body.Longitudinal axis is located at the midpoint between two substrates of cylinder, and puts down
Row is in the substrate of cylinder.Cylinder can have any aspect ratio, but for simplicity, term " long axis " is referred to all the time
The axis at the center in the face of connecting cylinder body.Note:For the cylinder of non-right circular cylinder, the long axis can be not orthogonal to
Cylinder substrate.
Fig. 1 to Fig. 4 shows a kind of embodiment, wherein by applying the rotation with zero field gradient or insignificant field gradient
Transition rotates manipulation to realize.Rotating excitation field can be provided by the permanent magnet of electromagnetism.Can apply 100Hz to 1000Hz (or
Other values) speed.In the present embodiment, by applying the magnetic field (H with ferromagnetic particlesParticle) abreast align
Rotating excitation field (HRotate-zero-gradient) realize translational motion.In the orientation, the rotation of particle is caused by rotating excitation field.Work as grain
Magnetic field (the H of sonParticle) and rotating excitation field (HRotate-zero-gradient) with phase when only realize particle rotate.As the magnetic field (H of particleParticle) with rotating
Magnetic field (HRotate-zero-gradient) into 180 degree out-phase when, realize particle rotation and particle translation.
As adjustment rotating excitation field (HRotate-zero-gradient) cause itself and particle magnetic field (HParticle) into 180 degree out-phase when, rotating excitation field
Magnetic north alignd with the magnetic north of particle." magnetic north " of rotating excitation field is generated particle movement far with aliging for " magnetic north " of particle
From the repulsive force in the source of rotating excitation field.The same magnetic south to particle in the magnetic south direction of rotating excitation field is acted.Match somebody with somebody at this
In putting, on the direction that gradient reduces, source of the particle away from rotating excitation field is guided.In the present embodiment, cylinder is by diameter
It is magnetized.When the magnetic moment of cylinder aligns in the plane parallel with the face of cylinder, there is the intensity of magnetization of diameter.Cause
This, the magnetized particles on the direction of the minor axis of cylinder.
As shown in Figs. 1-4, particle is cylinder form and particle is magnetized diametrically.It is understood, however, that
It is that same principle can be applied to many shapes of particle and can be applied to by otherwise magnetized particle.
Although further, it is understood that being illustrated that single particle into Fig. 4 in Fig. 1, disclosed embodiment is fitted
For manipulating multiple such particles (not considering shape), for example, the set of many such particles.
According to disclosed embodiment, due to the uniform rotation with zero magnetic field gradient or insignificant magnetic field gradient
Magnetic field (HRotate-zero-gradient), thus the particle of the particle or bigger of nanoscale (such as 30nm or smaller) size can surround one axle
Line is rotated.
Although paragraph [0023] describes an embodiment of the invention, wherein driving rotating excitation field (HRotate-zero-gradient) with
Magnetic field (the H of particleParticle) into the out-phase of 180 degree, but other embodiments may include the magnetic field (H of particleParticle) other into some
The out-phase of angular values.
Such as shown in Fig. 1 into Fig. 4, disclosed embodiment uses at least one particle 130, and the particle 130 is included
At least one magnetic part 140 or magnetizable part 140.Particle 130 can be by polymer, metal, insulator, half
Conductor, ceramics, any combination of nano material or these materials are constituted.In addition, particle 130 can be solid, hollow, many
Hole, two-phase, multiphase, coaxial or these structures any mixing.Particle 130 can include at least one magnetizable portion
Points 140, in order to illustrate, the magnetizable part 140 show Fig. 1 into Fig. 4 on the direction that empty arrow 160 is indicated
The intensity of magnetization 160.Alphabetical " N " and " S " is respectively used to represent for the magnetic field 150 and 155 applied and the magnetic group of particle
Into " north " magnetic pole and " south " magnetic pole of part 140.
Therefore, Fig. 1 to Fig. 4 depicts the particle 130 in each magnetic field provided by magnet 150 and magnet 155.Face
Plate (panel) 10 (Fig. 1), panel 20 (Fig. 2), panel 30 (Fig. 3) and each point in panel 40 (Fig. 4) the expression time.
In the disclosure, it should be understood that the intensity of magnetization orientation 160 of particle can be provided by applying by one or more magnets 150
Initial magnetic field set, as shown in the panel 10 in Fig. 1.Before being placed in particle manipulation device, the magnetic sections of particle
It can be magnetized for 140 or magnetisable section 140, as shown in the panel 10 in Fig. 1.The cylindrical particle 130 shown in Fig. 1 into Fig. 4
In the case of, particle magnetisation 160 can be on the direction parallel with the face of cylinder (intensity of magnetization of diameter).
In stable magnetic field, such particle 130 can align with magnetic field.In sufficiently strong and slow enough rotating excitation field
(HRotate-zero-gradient) in, at 20 (shown in Fig. 2) places, particle can in phase rotate with the magnetic field applied.For given magnetic field,
Rotating excitation field and particle are driven by with the rotating excitation field of given viscosity (viscosity for surrounding particle) and given maximum driving
(HRotate-zero-gradient) the same phase of frequency holding.In the configuration at the time 20, particle 130 will keep the rotating excitation field 155 with being applied
(HRotate-zero-gradient) orient to antiparallel, and with the (H of rotating excitation field 155 that is appliedRotate-zero-gradient) same to phase.Because the rotation applied
(the H of magnetic field 155Rotate-zero-gradient) be powered by a power supply, thus the rotating excitation field (H appliedRotate-zero-gradient) the scope of speed can be from
Less than 100Hz to more than 1000Hz.
The speed of particle is by rotating excitation field (HRotate-zero-gradient) driving, and it is received through surrounding viscosity, the magnetic field of material
Intensity and particle magnetic property and physical constraint placed on it.Particle rotation at 20 can be by with negligible
Field gradient rotating excitation field (HRotate-zero-gradient) realize.During same phase rotation at the time 20, the magnetic sections 140 of particle can
Align 160 with the antiparallel of rotating excitation field 155 that is applied.Therefore, particle only rotates.Therefore, according to disclosed embodiment party
Formula, translational motion is decoupled with rotary motion.In order to describe the purpose of disclosed the embodiment, " rotation of decoupling of term particle
Turn and translate " mean independently control rotation and translation outside particle, and will not substantially change the shape of particle.
According to disclosed embodiment, translation fortune can be realized by changing two parameters of applied rotating excitation field
It is dynamic.In such implementation, at 30 (figure 3 illustrates) places, the speed in adjustable rotating magnetic field 155 causes particle
130 fall behind about 180 degree than rotating excitation field 165.This can be realized by various methods, including:Increase rotation when particle rotates
Transition frequency, reduction magnetic field intensity or increase surround the viscosity of the material of particle to increase the towing on the particle.Because rotation
The magnetic field of magnetic field and particle into about 180 degree out-phase, so the rotating excitation field and the magnetic field (H of particle of drivingParticle) can be parallel to each other
Align on ground.
Then, at time 40 (Fig. 4) place, magnetic field gradient 190 can be added to rotating excitation field 155.Therefore, can produce with
Improved repulsive force on the vertical direction of the vector of the intensity of magnetization 165 of particle.As shown in Figures 1 to 4, repulsive force can be
On the direction that magnetic gradient reduces.Therefore, according to disclosed embodiment, rotating excitation field can drive particle to rotate, and field gradient
Translational motion can be caused.Therefore, according to disclosed embodiment, translation can be caused in the case where causing translational motion or not
Rotary motion is realized in the case of motion.
According to disclosed embodiment, magnetic field can pass through existing invention by Irving doctors Weinberg (including U.S.
State's patent 8,466,680 and United States Patent (USP) 8,154,286 (full content of the two is incorporated by reference into herein) and by it
The related application (by cross reference, as priority or be incorporated to) of submission) partially or completely describe
The device of electromagnet and/or permanent magnet applies.
For example, as taught in these publications, the magnetic field applied can have very short conversion time, so that
Uncomfortable sensation on body will not be caused.More specifically, by Aleksandar N.Nacev and Irving N.Weinberg
In " Pulsed Gradient Field Method to Counteract a submit, entitled on October 2nd, 2015
Static Magnetic Field for Magnetic Particle Focusing " existing U.S. Patent application 14/
In 873,738 (entire contents are incorporated by reference into), the strategy of propelling particles is disclosed, wherein, first will be magnetizable
Particle polarizes and/or alignd in one direction, (is, for example, less than in a short time then that it expends to polarize to decay
Time), the magnetic field on other direction is applied to the particle of initial polarization.As disclosed in Nacev and Weinberg, this plan
Slightly can be using multiple.
Disclosed embodiment can also by combine be submitted on 2 18th, 2014 it is entitled " SYSTEM,
METHOD AND EQUIPMENT FOR IMPLEMENTING TEMPORARY DIAMAGNETIC PROPULSIVE
FOCUSING EFFECT WITH TRANSIENT APPLIED MAGNETIC FIELD PULSES " U.S. Patent Publication
Technology disclosed in 20140309479 (entire contents are incorporated by reference into herein) is realized.It will therefore be appreciated that
It is that disclosed embodiment can be used for applying repulsion (for example, diamagnetic) power and/or promote (for example, attracting by combining
) power realized with manipulating the generation and application in the magnetic field of one or more magnetizable particles, for example by set up have it is pre-
Polarization pulse manipulates one or more magnetizable particles without the suitable magnetic gradient field of pre-polarizing pulse.
In addition, the composition of particle can include many different materials or thing for being loaded into particle or being loaded on particle
Body.These materials or object may include medicine, protein, other particles, molecule or cell.Particle may also comprise electronic unit,
Electronic unit includes capacitor, resistor, diode, transistor or energy gathering devices (such as glucose fuel cell).
Alternatively, disclosed embodiment, which can be used, can be partially coated with the superparamagnetism grain of ferromagnetism component
Son.Ferromagnetic fraction can have magnetized section of (M of long axis perpendicular to particle2, particle).This configuration is shown in the face shown in Fig. 5
In plate 201.In such embodiment, ferromagnetic layer 340 can be only the cumulative volume of whole particle 300 in volume
0.1%.In one implementation, the main body (bulk) of particle 300 can be made up of the superparamagnetic material with magnetic moment 335,
The magnetic moment 335 magnetic field random external orient.Note, the superparamagnetism part of particle 300 will have very close to ferromagnetic
Property layer 340 section, this section abreast align with the intensity of magnetization of ferromagnetic layer 340.The magnetic moment of superparamagnetic material is in magnetic field
It is outside substantially unordered.Although thin ferromagnetic layer 340 provides some local magnetic fields really, the magnetic field is faint, and only
Influence the sub-fraction of the magnetic moment of the main body superparamagnetic material of particle.Therefore, as shown in Figure 6, can be by the way that particle 300 be put
The operation for the magnetic moment 340 for magnetizing thin ferromagnetic layer is provided in the magnetic field provided by magnet 299.Therefore, particle 300 is super
The magnetic moment 335 of paramagnetism main body also aligns with this.However, once removing magnet, the intensity of magnetization of superparamagnetism main body also will
Nile relaxation is undergone, as shown in Fig. 7 to Fig. 8.
In at least one embodiment, particle can be more than the cylinder of width (for example aspect ratio is more than 1) using length
Shape.In this configuration, there may be interaction between the magnetic moment of the main body of particle 300, this can strengthen particle 300 with
The magnetic alignment in the magnetic field applied.This power can be directly opposite with the behavior of aliging of thin ferromagnetic layer 340.
According at least one disclosed embodiment, thin ferromagnetic layer magnetic moment 340 can magnetize 345 (M by diameter2, particle);
Therefore, applying at least some designed magnetic fields can cause the long axis of particle and magnetic field vertically aligned.
In addition, at least one embodiment of the present invention, the long axis of particle can with the field intensity of a scope
Magnetic field antiparallel align, and the particle long axis can with it is vertically aligned with the magnetic field of the field intensity of another scope.This
The energy that the thin ferromagnetism section magnetic moment 340 of particle 300 or the magnetic moment 335 of superparamagnetism section main body align with magnetic field can be attributed to
Amount balance.When the motive force of the dipole-dipole alignment in the magnetic moment 335 for the superparamagnetism main body of particle is overcome particle
Thin ferromagnetic layer 340 and magnetic field vertical alignment energy battier when, being alignd with the superparamagnetism main body of particle 300 to account for
Wind.
In the presence of two kinds of particle alignment patterns.A kind of pattern is referred to alternatively as " based on main body " alignment pattern.Another mould
Formula is referred to alternatively as " based on thin layer " alignment.Alignment based on main body and the alignment based on thin layer can be due to passing through magnet
399 apply magnetic fields and produce.Magnet 399 can be electromagnet, permanent magnet or some combinations of the two.Based on main body
During alignment, the long axis of particle can align with the magnetic field applied and (be shown in Fig. 7 panel 301).Based on thin layer
Alignment during, the long axis of particle can be with the magnetic field vertical alignment (being shown at Fig. 8 panel 302) that is applied.
Fig. 4 shows the configuration according to disclosed embodiment offer, to provide rotation to a particle or multiple particles
Turn the combination of power and propulsive force.As shown in the panel 410 in Fig. 9, all magnetic fields of removable application.Consequently, because particle
300 main body is superparamagnetism, so the magnetic moment 335 of the main body of particle can undergo Neel relaxations 335.It is understood, however, that
, the magnetic moment of the ferromagnetic layer of particle is because they are ferromagnetic and undergo insignificant nile relaxation.
Then, in time or stage 420, rotating excitation field 500 can be applied.The rotating excitation field 500 can be used based on thin layer
Alignment pattern.Therefore, at 420 (Figure 10), apply it is orthogonal with the long axis of particle and with the magnetic moment of thin ferromagnetism section 340
Parallel magnetic field.Therefore, the intensity of magnetization of the superparamagnetism section 335 of particle 300 can be reordered, with perpendicular to the length of particle
Axis is arranged.
However, significantly, particle will not be redirected to alignd with magnetic field (as shown in the 301 of Fig. 7) in itself;Because
Rotating excitation field 500 significantly than the 301 of Fig. 7 in the aligned magnetic field that shows it is weak.Magnetic field can add, therefore rotating excitation field is with aliging
Magnetic field combination produces precession (precessing) magnetic field, wherein, precession has some angles of the axis away from rotating excitation field.
The aligned magnetic field shown in the 301 of Fig. 7 can be removed or decay, and only rotating excitation field 500 is present in Fig. 8.Cause
This, by the thin ferromagnetism section 340 and (H of rotating excitation field 500 for allowing particle 300Rotate-zero-gradient) align to realize the energy of system
Minimum value.Such as shown at 420 (Figure 10) places and 430 (Figure 11) places, the long axis due to rotating field 500 around particle rotate
(dotted line at 420,430), thus particle 300 can be around the rotation of its long axis.After rotating field is applied, rotation can be removed
Field magnets, and the experience nile relaxation of magnetic moment 335 of the superparamagnetism main body of particle can be made.
, can be by making what is applied in panel 420 (Figure 10) and panel 430 (Figure 10) as shown in panel 440 (Figure 12)
(the H of rotating excitation field 500Rotate-zero-gradient) with the propulsion magnetic field (H that is shown in panel 450 (Figure 13) and panel 460 (Figure 14)Zero-gradient) hand over
Fork, to realize translational thrust.Strong magnetic field gradient (H is applied by using magnet 510Zero-gradient), the superparamagnetism main body of particle will have
There is the magnetic moment 335 temporarily alignd with the strong aligned magnetic field antiparallel produced by a pair of magnets 510.It should be understood that by Figure 13
In the aligned magnetic field that produces of magnet 510 can be realized by application electromagnet or permanent magnet.
The overall physical alignment of particle 300 in space can be realized by strong aligned magnetic field.Applying strong aligned magnetic field
Period, the superparamagnetism magnetic moment 335 of particle main body can make greater efforts to promote along the long axis of particle 300 and aliging for magnetic field.Due to
Particle 300 is mainly made up of superparamagnetic material, thus can be by the grain that is alignd with the strong aligned magnetic field produced by magnet 510
Son 300 obtains energy-minimum.On the contrary, ferromagnetism part 340 can have the magnetic moment 345 orthogonal with strong aligned magnetic field.This
It is due to that oppressive alignment force caused by the superparamagnetism magnetic moment 335 of particle main body is made greater efforts to promote at 450 and magnetic field
Alignment.
Can be by removing aligned magnetic field (HZero-gradient) magnet 510 and be applied on the direction with aligned magnetic field antiparallel 520
Magnetic field gradient (HWith-gradient) fast-pulse realize propulsion.As a result can be with previously by Aleksandar Nacev and
The similar propulsive force 530 of propulsive force disclosed in Irving Weinberg.
In such embodiment, reference picture 9 to Figure 14, the operation performed in panel 410 into panel 460 can be represented
Order point in time.These operations may be such that strong aligned magnetic field and rotating excitation field are intersected, to realize the alignment of particle at 430
Manipulation and rotation manipulation.Therefore, can be by intersecting magnetic pulse with sequentially by means of parallel right at least present embodiment
Magnetic field gradient (the H of neat or antiparallel alignmentWith-gradient) come the particle that aligns, translation particle, and by with zero gradient or negligible
Gradient rotating excitation field (HRotate-zero-gradient) carry out rotating particle, so as to realize rotation and translation.
The application of disclosed embodiment can change.Tissue and fluid in body are with the non-of viscoelastic property
Newtonian material, the viscoelastic property hinders motion of the particle under magnetic guiding.It is known that very small bubble can change
Motion of the particle in viscous fluid, such as by A.Maali and B.Bhushan 2013 (25) periodical《Physics:
Condensed Matter》Page 184003 publication, entitled " Nanobubbles and their role in slip
Taught in and drag " article (entire contents are incorporated by reference into).
Embodiment disclosed in this invention can integrally be realized or partly realized, to enable the particles to rotation, be used to
Produce the bubble and/or vacuum (such as air pocket) close to particle.Therefore, air pocket can as particle surface and surrounding medium it
Between lower resistance demarcate and be used for lubricant particles.In other embodiment, magnetic resonance, ultrasonic wave or reference are being utilized
And during the other known imaging technique observation for the discussion being incorporated herein, air pocket can be by increasing effective highlighting of particle
Help to be imaged particle.
In other embodiment, magnetic resonance, ultrasonic wave or reference and the discussion that is incorporated herein are being utilized
During other known imaging technique observation, rotation can be used for carrying out into particle by increasing effective highlighting of particle
Picture.For example, the rotation of particle can influence particle to striking the absorption or reflection of the energy of the particle from source.
In addition, disclosed embodiment can be used for one with length-specific or length ratio by manufacturing particle
Or multiple magnetic parts are come the part for increasing particle and the coupling efficiency in the magnetic field applied.As an example, as shown in Figure 15,
The cylinder of the magnetic sections of two times of big length with than cylinder diameter is by the easy magnetization with the length along cylinder
Axis.Bar length with particular directions from magnetized relation, by Love etc. 2003 (125) periodical《American
Chemical Society》Page 12696 to 12697 publication their publication " Three-Dimensional Self-
Assembly of Metallic Rods with Submicron Diameters Using Magnetic
Instructed in Interactions " (entire contents are incorporated by reference into herein).
Realize the magnetic sections (M on the magnetized cylinder of the long axis of cylinder2, particle) a method can lead to
Cross so that diameter of the magnetic sections than cylinder in itself is short realizes.Therefore, can be by forming at least two on single cylinder
Magnetic sections are manufactured with vertical hardening strength M1, particleAnd M2, particleCylinder, as shown in Figure 15 stage 700.Therefore, may be used
(the M of one or more magnetic sections 710 of the length of at least twice with cylinder diameter is provided1, particle) and with more straight than cylinder
One or more sections of 720 (M of the small length in footpath2, particle), each magnetic sections is separated by nonmagnetic substance 730.As in Figure 15
Shown, arrow represents section 710, the direction of magnetization of each of section 720.
Figure 16 shows the example of the operation of the device according to disclosed embodiment offer.As shown in Figure 16, carry
For multiple (such as four) electromagnets 903 and a permanent magnet 906, to manipulate particle 905 in a prescribed manner.It is noted that
, the electromagnet in Figure 16 can provide the magnetic field with zero gradient or insignificant gradient.Again, it should be noted that Figure 16
In the particle that shows can have two kinds of intensity of magnetization being loaded on single particle.Shown with the arrow in the main body of particle 905
Go out each direction of magnetization.In operation, the device is combined with computer 901 and produced using computer 901 for driving four
The signal of individual electromagnet 903.Computer 901 can be replaced by that can supply another signal generating apparatus of electric current to electromagnet 903
Generation.For example, the power supply of pulse can be used.By before being sent to electromagnet 903 as the signal produced by computer 901, it can lead to
Cross amplifier 902 and amplify the signal.
Figure 16 also illustrates that electromagnet can be driven by double-channel signal;However, twin-channel demonstration is intended merely as showing
Example property.It should be understood that disclosed embodiment may include two electromagnets, eight electromagnets or more electromagnetism
Body.Similarly, electromagnet can by the single channel signal from computer 901 or other signal generators, from computer 901 or
The signal of eight channel signals of other signal generators or more passage drives.In addition, electromagnet may be used in RF pulses
Particle is encouraged, to heat the particle, so as to partly cause hyperpyrexia.
Figure 16 demonstrates the rotation by long axis produced by the rotating field that is provided as electromagnet 903, around bar
904.Permanent magnet 906 can be used for providing magnetic field gradient.It should be understood that the magnetic field gradient can be produced using electromagnet, and
Process it can change amplitude and frequency over time.
It should be understood that the operation explained herein can combine one or more all-purpose computers to realize, or
Person gets off realization in the control of one or more all-purpose computers, and one or more all-purpose computer runs software algorithms are to carry
It is changed into special-purpose computer for function disclosed in this invention, and by these computers.
In addition, it would be recognized by those skilled in the art that when considering above technology, foregoing exemplary embodiment can be based on
Use the processor for the one or more programmings for being programmed with suitable computer program.However, hardware component equivalent can be used
(such as specialized hardware and/or application specific processor) realizes disclosed embodiment.Similarly, can be used all-purpose computer,
Computer, microcontroller, optical computer, simulation computer, application specific processor, special circuit based on microprocessor and/or specially
Hardwire logic constructs the equivalent embodiments of alternative.
Further, it is understood that software instruction can be used provide be used for apply it is described herein manipulation one or
The control and cooperation of the part (such as magnet) of the instrument in the magnetic field of multiple particles, the software instruction is storable in tangible, non-
In temporary storage device (the non-transitory computer readable storage devices of such as store instruction), compiled when one or more
When the instruction is performed on the processor of journey, the function that above-mentioned method is operated and obtained is performed.In this case, term is " non-
It is temporary " ripple that is intended to exclude the signal of transmission and propagates, rather than exclude it is erasable or depending on power supply to keep letter
The storage device of breath.
Therefore, such instrument may include one or more controllable Electromagnetic Sources and this paper produced can be controlled to be retouched
The controller in the magnetic field stated.In such implementation, it can make in the case where the control of controller of gradient can be controlled
One or more gradient coils are used, to produce one or more magnetic fields using at least one coil actuator, wherein providing one
Or multiple coils for RF energy is sent to as diagnosis, forecast and/or processing part body part tissue sample
In this.
It will be understood by those skilled in the art that when considering above technology, the program for realizing some above-mentioned embodiments
Operation and processing and associated data can use the storage device of jukebox storage and other forms to realize, other
The storage device of form include but is not limited to non-transitory storage medium (wherein, non-transitory be intended merely to exclude transmitting signal, and
It is not as the temporary signal by removing power supply or being wiped free of by clear and definite erasing move), it is such as read-only
Memory (ROM) equipment, random access memory (RAM) equipment, the network storage equipment, optical memory element, magnetic memory,
Magneto-optical storage elements, flash memory, core memory and/or the other equivalent volatibility for not departing from some embodiments of the invention
Memory technology and nonvolatile storage technologies.The storage device of such alternative is considered as equivalent.
According at least one embodiment there is provided for making the apparatus and method of particle rotation and translation, wherein, particle
At least certain part or certain part include magnetisable material, wherein, the rotation of particle and the translational motion of particle are decouplings
's.For purposes of this disclosure, term " decoupling " means to change the ratio between the point-to-point speed and rotary speed of particle
Ability.The decoupling is unlike the prior art, for example, in the prior art, magnetic particle has been manufactured or configured to spiral shell
Shape or arc are revolved, to creep into medium or through medium.In such an example, the ratio of point-to-point speed and rotary speed
It is not variable, because the ratio is set by the geometry of spiral shape or arc.The example of prior art passes through UK
Periodicals of Cheang, F Meshkali, D Kim, MJ Kim and H C Fu in 2014 years《Physical Review E》(the
Volume 90,033007) entitled " Minimal geometric requirements for micrpropulsion via
Magnetic rotation " article is proposed.
According at least one embodiment, particle can have the section of the such feature of band:With approximate 1 nanometer of size or
Bigger arbitrary dimension.
According at least one embodiment, the scope for being applied to the rotating field of particle can be from 1Hz to 1000Hz.
According at least one embodiment, the electromagnet for manipulated particle can be manipulated into the alternate magnetic of generation
.The electromagnet can be operated with radio frequency, and the operation can be used for the quick change of the magnetic domain of excitation particle.The magnetic of particle
The quick change on farmland can be used for being converted to the magnetic energy being switched fast the heat energy sent from particle.
According at least one embodiment, particle can by polymeric material, metal material, insulating materials, semi-conducting material,
Any combination of ceramic material or these materials is constituted.According at least one embodiment, particle can accommodate electronics, molecule/medicine
Thing, protein, cell or energy harvesting components.
According at least one embodiment, particle can carry what can be lighted and (for example be lighted by carrying phosphorescent material)
Section, or RF can be used and heated section, the RF for supplying heat energy to carry out high heat treatment.Caused by magnetic particle
Hyperpyrexia is such technique:By the technique, alternate magnetic field is used to encourage the magnetic particle being placed in human body or animal body.
Alternate field excitation can be performed with radio frequency.Particle excitation causes heating particulates.The heating can be used for destruction or kill in grain
Cell near son.By using magnetic field and field gradient come the magnetic particle that localizes, the heat energy of release can be aligned to surround and be somebody's turn to do
The region of particle, such as International Periodicals by Andre C.Silva in 2011《Nanomedicine》Volume 6, the 591st to
Publication " the Application of hyperthermia induced by superparamagnetic of the publication of page 603
Taught in iron oxide particles in glioma treatment ".
According at least one embodiment, the rotation of particle reduces the effective resistance for motion.For having for motion
Reducing for effect resistance can be realized by the local virtual viscosity for reducing surrounding biologic material, tissue or fluid.For example, being organized as
The thinning material of shearing.This means when being applied to the shearing increase of tissue, the virtual viscosity of tissue reduces.The rotation of particle
The shearing force around particle is generated, and the shearing force can reduce the virtual viscosity of the tissue of particle periphery.In addition, being applied
Shearing force can cause to move barrier, such as protein to be moved caused by the shearing force of generation or patch it is poly-
Collection.Alternatively, shearing force can be used for causing translation of the particle on the direction vertical with translation direction.
According at least one embodiment, the rotation of particle adds the highlighting under imaging.According at least one implementation
Mode, solution includes multiple particles and/or multiple different types of particles, i.e. accommodate the set of the particle of electronics, and/or bag
The set of particle containing molecule/medicine, and/or operation are the set of the particle of energy harvesting components.According at least one implementation
Mode, the rotation of particle increases the point-to-point speed in medium.Medium can be Newtonian or non-Newtonian.According to extremely
A few embodiment, if particle carries pay(useful) load (such as medicine), the rotation of particle changes the release of pay(useful) load
Speed.According at least one embodiment, the rotation of particle comes for example by the pressurization of the connector portions between the part to particle
Change the speed or pattern of the degeneration of particle.
Shown embodiment includes being used to make the device of at least one particle rotation and translation, and the device includes:With
In the mechanism for producing magnetic force and magnetic torque;And at least one particle, wherein, at least certain part bag of at least one particle
Containing magnetisable material, wherein, produced magnetic force is applied at least certain part of at least one particle, to cause particle
Translational motion, wherein, produced magnetic torque is applied at least certain other parts of at least one particle of identical, to draw
The rotation of particle is played, and wherein, the point-to-point speed of particle and the ratio of rotary speed are changes.
Shown embodiment includes such embodiment, wherein, particle is introduced in body, and when particle exists
When in body, the point-to-point speed of particle and be change with the ratio of rotary speed.
Shown embodiment includes such embodiment, wherein, include being used to produce for producing the mechanism of magnetic force
The mechanism of rotating field of the raw scope from 1Hz to 1000Hz.
Shown embodiment includes such embodiment, wherein, at least one particle is by polymeric material, gold
At least both combinations belonged in material, insulating materials, semi-conducting material, ceramic material or these materials are constituted.
Shown embodiment includes such embodiment, wherein, at least one particle receiving electronics, molecule/
Medicine, protein, cell or energy harvesting components.
Shown embodiment includes such embodiment, wherein, at least one particle carries what can be lighted
Section.
Shown embodiment includes such embodiment, wherein, at least one particle can use radio frequency spoke
Penetrate to heat.
Shown embodiment includes such embodiment, wherein, at least one particle can be used alternately
Magnetic field is heated.
Shown embodiment includes such embodiment, wherein, at least one particle can carry effectively negative
Carry.
Shown embodiment includes such embodiment, wherein, the rotation of at least one particle reduce for
The effective resistance of motion.
Shown embodiment includes such embodiment, wherein, the rotation of at least one particle is added to picture
Under highlighting.
Shown embodiment includes such embodiment, wherein, the rotation of at least one particle increases in matchmaker
Point-to-point speed in Jie.
Shown embodiment includes such embodiment, wherein, the rotation modification of at least one particle is included
The release of pay(useful) load at least one particle.
Shown embodiment includes such embodiment, wherein, the rotation of at least one particle changes this extremely
The degeneration of a few particle.
Shown embodiment includes such embodiment, wherein, the rotation of at least one particle and this at least
At least one of translational motion of decoupling of one particle is used for applying repulsive force and/or propulsive force to manipulate this by combining
The generation and application in the magnetic field of at least one particle and realize.Shown embodiment includes such embodiment, wherein,
By setting up with pre-polarizing pulse or being performed without the suitable magnetic gradient field of pre-polarizing pulse at least one particle
Manipulation.
Shown embodiment includes such embodiment, and the embodiment also includes including the molten of multiple particles
Liquid, each particle that the multiple particle is included at least one particle, the plurality of particle includes including magnetisable material
Certain part or certain part, wherein, cause the magnetic torque of the rotation of each particle in multiple particles and cause translational motion
Magnetic force decoupling.
Shown embodiment includes such embodiment, wherein, cause the magnetic of the rotation of at least one particle
The amplitude and frequency of the magnetic field gradient of translation of the amplitude and frequency of field with causing at least one particle are independent.It is shown
Embodiment include such embodiment, wherein, the amplitude for causing magnetic field gradient that at least one particle translates
It is constant in time.Similarly, shown embodiment includes such embodiment, wherein, the width of magnetic field gradient
Degree is change in time.
Shown embodiment includes being used to make the method for at least one particle rotation and translation, and this method includes:Pin
At least one particle is produced and applies magnetic force and magnetic torque, wherein, at least one particle include at least two sections, it is described extremely
Each of few two sections include magnetisable material;Magnetic force is applied at least one section, so as to cause the translation of particle to be transported
It is dynamic;And, magnetic torque is applied to at least one other section, so as to cause the gained of the rotary motion of particle, wherein particle
To point-to-point speed and rotary speed ratio be change.
Shown embodiment includes such embodiment, wherein, particle is introduced in body, and works as particle
When in the body, the point-to-point speed of particle and be change with the ratio of rotary speed.
Shown embodiment includes such embodiment, wherein, the generation of magnetic force to produce scope from 1Hz to
1000Hz rotating field.
Shown embodiment includes such embodiment, wherein, at least one particle is by polymeric material, gold
At least both combinations belonged in material, insulating materials, semi-conducting material, ceramic material or these materials are constituted.
Shown embodiment includes such embodiment, wherein, at least one particle receiving electronics, molecule/
Medicine, protein, cell or energy harvesting components.
Shown embodiment includes such embodiment, wherein, at least one particle carries what can be lighted
Section.
Shown embodiment includes such embodiment, wherein, at least one particle can use radio frequency spoke
Penetrate to heat.
Shown embodiment includes such embodiment, wherein, at least one particle can be used alternately
Magnetic field is heated.
Shown embodiment includes such embodiment, wherein, at least one particle can carry effectively negative
Carry.
Shown embodiment includes such embodiment, wherein, the rotation of at least one particle reduce for
The effective resistance of motion.
Shown embodiment includes such embodiment, wherein, the rotation of at least one particle is added to picture
Under highlighting.
Shown embodiment includes such embodiment, wherein, the rotation of at least one particle increases in matchmaker
Point-to-point speed in Jie.
Shown embodiment includes such embodiment, wherein, the rotation modification of at least one particle is included
The release of pay(useful) load at least one particle.
Shown embodiment includes such embodiment, wherein, the rotation of at least one particle changes this extremely
The degeneration of a few particle.
Shown embodiment includes such embodiment, wherein, the rotation of at least one particle and this at least
At least one of translational motion of decoupling of one particle is used for applying repulsive force and/or propulsive force to manipulate this by combining
The generation and application in the magnetic field of at least one particle and realize.
Shown embodiment includes such embodiment, wherein, by setting up with pre-polarizing pulse or not having
There is the suitable magnetic gradient field of pre-polarizing pulse to perform the manipulation at least one particle.
Shown embodiment includes such embodiment, wherein, at least one particle is in multiple particle
One particle, wherein, each particle in the plurality of particle includes certain part comprising magnetisable material or certain part, its
In, cause magnetic torque and cause the magnetic force of translational motion to decouple that each particle in multiple particles rotates.
Shown embodiment includes such embodiment comprising the solution of multiple particles includes this at least
Each particle in one particle, the plurality of particle includes certain part comprising magnetisable material or certain part, wherein, draw
Play the magnetic torque of the rotation of each particle in multiple particles and cause the magnetic force of translational motion to decouple.
Shown embodiment includes such embodiment, wherein, cause the magnetic of the rotation of at least one particle
The amplitude and frequency of the magnetic field gradient of translation of the amplitude and frequency of field with causing at least one particle are independent.It is shown
Embodiment include such embodiment, wherein, the amplitude for causing magnetic field gradient that at least one particle translates
It is constant in time.Similarly, shown embodiment includes such embodiment, wherein, the width of magnetic field gradient
Degree is change in time.
Although it have been described that some illustrated embodiments, it is apparent that according to described above, many alternatives, repair
Change, replace and modification will become obvious for those skilled in the art.Although having been described above shown by outlining
Embodiment, it is apparent that many alternatives, modifications and variations will be apparent for those skilled in the art.Therefore,
Each embodiment of the present invention as described above is intended to illustrate, rather than is limited.Various changes can be carried out without de-
From the spirit and scope of the present invention.
Therefore, it will be apparent to one skilled in the art that described illustrated embodiment is merely illustrative, and
Various modifications can be carried out in the scope of the present invention such as defined in the appended claims.
Claims (20)
1. a kind of be used to make the device of at least one particle rotation and translation, described device includes:
Mechanism for producing magnetic force and magnetic torque;
At least one particle, wherein, at least certain part at least one described particle includes magnetisable material,
Wherein, the produced magnetic force is applied at least certain part of at least one particle, to cause the particle
Translational motion,
Wherein, the produced magnetic torque is applied at least certain other parts of at least one particle described in identical, with
Cause the rotation of the particle, and
Wherein, the ratio of the point-to-point speed of the particle and rotary speed can change.
2. device according to claim 1, wherein, the particle is introduced in body, and when the particle is in institute
When stating in body, the point-to-point speed of the particle and the ratio of the rotary speed are changes.
3. device according to claim 1, wherein, for produce the mechanism of magnetic force include being used for producing scope from
The mechanism of 1Hz to 1000Hz rotating field.
4. device according to claim 1, wherein, at least one described particle is by polymeric material, metal material, insulation
At least both combinations in material, semi-conducting material, ceramic material or these materials are constituted.
5. device according to claim 1, wherein, at least one described particle accommodate electronics, molecule/medicine, protein,
Cell or energy harvesting components.
6. device according to claim 1, wherein, the rotation of at least one particle and at least one described grain
At least one of described translational motion of decoupling of son by with reference to for applying repulsive force and/or propulsive force with described in manipulating
The generation and application in the magnetic field of at least one particle and realize.
7. device according to claim 1, wherein, by setting up with pre-polarizing pulse or without pre-polarizing pulse
Suitable magnetic gradient field performs the manipulation at least one particle.
8. device according to claim 1, wherein, at least one described particle is a particle in multiple particles, its
In, each particle in the multiple particle includes certain part comprising magnetisable material or certain part, wherein, cause institute
State the magnetic torque of the rotation of each particle in multiple particles and cause the magnetic force of translational motion to decouple.
9. device according to claim 1, in addition to include the solution of multiple particles, the multiple particle include it is described extremely
A few particle, wherein, each particle in the multiple particle includes certain part comprising magnetisable material or certain composition portion
Point, wherein, cause the magnetic torque of the rotation of each particle in the multiple particle and cause the magnetic force solution of translational motion
Coupling.
10. device according to claim 1, wherein, cause the magnetic field of the rotation of at least one particle amplitude and
The amplitude and frequency of the magnetic field gradient of translation of the frequency with causing at least one particle are independent.
11. a kind of be used to make the method for at least one particle rotation and translation, methods described includes:
Produced at least one particle and apply magnetic force and magnetic torque, wherein, at least one described particle includes at least two
Section, each of described at least two sections include magnetisable material;
The magnetic force is applied at least one section, so as to cause the translational motion of the particle;
The magnetic torque is applied to at least one other section, so that cause the rotary motion of the particle,
Wherein, the resulting point-to-point speed of the particle and the ratio of rotary speed can change.
12. method according to claim 11, wherein, the particle is introduced in body, and when the particle exists
When in the body, the point-to-point speed of the particle and the ratio of the rotary speed are changes.
13. method according to claim 11, wherein, the generation of the magnetic force to produce scope from 1Hz to 1000Hz
Rotating field.
14. method according to claim 11, wherein, at least one described particle is by polymeric material, metal material, absolutely
At least both combinations in edge material, semi-conducting material, ceramic material or these materials are constituted.
15. method according to claim 11, wherein, at least one described particle accommodates electronics, molecule/medicine, albumen
Matter, cell or energy harvesting components.
16. method according to claim 11, wherein, the rotation of at least one particle and it is described at least one
At least one of described translational motion of the decoupling of particle is used for applying repulsive force and/or propulsive force to manipulate by combining
State the generation and application in the magnetic field of at least one particle and realize.
17. method according to claim 11, wherein, by setting up with pre-polarizing pulse or without pre-polarizing pulse
Suitable magnetic gradient field perform the manipulation at least one particle.
18. method according to claim 11, wherein, at least one described particle is a particle in multiple particles,
Wherein, each particle in the multiple particle includes certain part comprising magnetisable material or certain part, wherein, cause
The magnetic torque of the rotation of each particle in the multiple particle is with causing the magnetic force of translational motion to decouple.
19. method according to claim 11 is comprising the solution of multiple particles includes at least one described particle,
Each particle in the multiple particle includes certain part comprising magnetisable material or certain part, wherein, cause described
The magnetic torque of the rotation of each particle in multiple particles is with causing the magnetic force of translational motion to decouple.
20. method according to claim 11, wherein, cause the magnetic field of the rotation of at least one particle amplitude and
The amplitude and frequency of the magnetic field gradient of translation of the frequency with causing at least one particle are independent.
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US201462073360P | 2014-10-31 | 2014-10-31 | |
US62/073,360 | 2014-10-31 | ||
PCT/US2015/058617 WO2016070180A1 (en) | 2014-10-31 | 2015-11-02 | Method and apparatus for non-contact axial particle rotation and decoupled particle propulsion |
Publications (2)
Publication Number | Publication Date |
---|---|
CN106999719A true CN106999719A (en) | 2017-08-01 |
CN106999719B CN106999719B (en) | 2020-08-14 |
Family
ID=55853416
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN201580059621.XA Active CN106999719B (en) | 2014-10-31 | 2015-11-02 | Method and apparatus for particle propulsion for non-contact axial particle rotation and decoupling |
Country Status (4)
Country | Link |
---|---|
US (1) | US10290404B2 (en) |
EP (1) | EP3212284B1 (en) |
CN (1) | CN106999719B (en) |
WO (1) | WO2016070180A1 (en) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN113712529A (en) * | 2020-05-24 | 2021-11-30 | 温伯格医学物理有限公司 | Method and apparatus for measuring and inactivating pathogens using in vivo magnetizable devices |
Families Citing this family (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN108814599A (en) * | 2017-03-16 | 2018-11-16 | 温伯格医学物理有限公司 | The method and apparatus of rapid evaluation and processing for wound |
US10888243B2 (en) | 2017-06-22 | 2021-01-12 | Weinberg Medical Physics Inc | Non-invasive method for focal deep-brain stimulation equipment and methodologies |
CN109381224A (en) * | 2017-08-02 | 2019-02-26 | 温伯格医学物理有限公司 | Using Magnetic driving capsule carry out tissue biopsy or removal or to tissue added material devices, systems, and methods |
JP2020042879A (en) * | 2018-09-12 | 2020-03-19 | キオクシア株式会社 | Magnetic storage device |
US20210322680A1 (en) * | 2020-04-17 | 2021-10-21 | Weinberg Medical Physics Inc | Method and apparatus for implementing magnetic micro-syringes |
Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US20070197953A1 (en) * | 2003-07-18 | 2007-08-23 | Slade Robert A | Magnetic particles for therapeutic treatment |
US20100259259A1 (en) * | 2005-09-21 | 2010-10-14 | Markus Zahn | Systems and methods for tuning properties of nanoparticles |
US20130079623A1 (en) * | 2010-04-01 | 2013-03-28 | Julius-Maximilians-Universitaet Wuerzburg | Imaging Method using Magnetic Small Particles and Corresponding Device |
Family Cites Families (17)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US4053433A (en) * | 1975-02-19 | 1977-10-11 | Minnesota Mining And Manufacturing Company | Method of tagging with color-coded microparticles |
US6002314A (en) * | 1999-02-11 | 1999-12-14 | Gray; Robert W. | Utilization of magnetic bubbles to produce a motive force |
US20040209376A1 (en) * | 1999-10-01 | 2004-10-21 | Surromed, Inc. | Assemblies of differentiable segmented particles |
EP1263532A2 (en) * | 2000-03-16 | 2002-12-11 | Sri International | Microlaboratory devices and methods |
US20020146745A1 (en) * | 2001-04-03 | 2002-10-10 | Surromed, Inc. | Methods and reagents for multiplexed analyte capture, surface array self-assembly, and analysis of complex biological samples |
CN1957251B (en) * | 2004-05-18 | 2010-11-03 | 皇家飞利浦电子股份有限公司 | Magnetic rotation to improve signal-over-background in biosensing |
GB0512402D0 (en) * | 2005-06-17 | 2005-07-27 | Oxford Instr Molecular Biotool | Method of providing magnetised particles at a location |
JP5452922B2 (en) * | 2005-09-13 | 2014-03-26 | アフィメトリックス・インコーポレーテッド | Coded microparticles |
WO2008021571A2 (en) * | 2006-08-18 | 2008-02-21 | Maglev Technologies, Llc. | Magnetic composites |
IT1392999B1 (en) * | 2009-02-12 | 2012-04-02 | Ct De Investigacion Cooperativa En Nanociencias Cic Nanogune Asoc | MANIPULATION OF MAGNETIC PARTICLES IN CIRCUITS FOR THE PROPAGATION OF MAGNETIC DOMAIN WALLS. |
US20110074231A1 (en) * | 2009-09-25 | 2011-03-31 | Soderberg Rod F | Hybrid and electic vehicles magetic field and electro magnetic field interactice systems |
CA2934401C (en) * | 2009-11-02 | 2017-01-10 | Pulse Therapeutics, Inc. | Magnetomotive stator system and methods for wireless control of magnetic rotors |
US20110215888A1 (en) * | 2009-11-12 | 2011-09-08 | University Of Utah | Wireless control of microrobots |
WO2011072060A2 (en) * | 2009-12-08 | 2011-06-16 | Magnetecs Corporation | Diagnostic and therapeutic magnetic propulsion capsule and method for using the same |
US9532729B2 (en) * | 2010-09-27 | 2017-01-03 | The General Hospital Corporation | Self-assembled magnetic arrays |
DE102010041621B4 (en) | 2010-09-29 | 2016-11-03 | Hahn-Schickard-Gesellschaft für angewandte Forschung e.V. | Method for transporting magnetic particles |
US9694196B2 (en) * | 2013-04-10 | 2017-07-04 | Weinberg Medical Physics Inc | System, method and equipment for implementing temporary diamagnetic propulsive focusing effect with transient applied magnetic field pulses |
-
2015
- 2015-11-02 CN CN201580059621.XA patent/CN106999719B/en active Active
- 2015-11-02 EP EP15855445.1A patent/EP3212284B1/en active Active
- 2015-11-02 WO PCT/US2015/058617 patent/WO2016070180A1/en active Application Filing
- 2015-11-02 US US14/930,126 patent/US10290404B2/en active Active - Reinstated
Patent Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US20070197953A1 (en) * | 2003-07-18 | 2007-08-23 | Slade Robert A | Magnetic particles for therapeutic treatment |
US20100259259A1 (en) * | 2005-09-21 | 2010-10-14 | Markus Zahn | Systems and methods for tuning properties of nanoparticles |
US20130079623A1 (en) * | 2010-04-01 | 2013-03-28 | Julius-Maximilians-Universitaet Wuerzburg | Imaging Method using Magnetic Small Particles and Corresponding Device |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN113712529A (en) * | 2020-05-24 | 2021-11-30 | 温伯格医学物理有限公司 | Method and apparatus for measuring and inactivating pathogens using in vivo magnetizable devices |
Also Published As
Publication number | Publication date |
---|---|
EP3212284B1 (en) | 2021-07-07 |
US20170069416A9 (en) | 2017-03-09 |
EP3212284A4 (en) | 2018-08-01 |
US20160125994A1 (en) | 2016-05-05 |
WO2016070180A1 (en) | 2016-05-06 |
EP3212284A1 (en) | 2017-09-06 |
US10290404B2 (en) | 2019-05-14 |
CN106999719B (en) | 2020-08-14 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
CN106999719A (en) | Method and apparatus for the particle advancing of contactless axial particle rotation and decoupling | |
Bente et al. | Biohybrid and bioinspired magnetic microswimmers | |
Peyer et al. | Magnetic helical micromachines | |
Rikken et al. | Manipulation of micro-and nanostructure motion with magnetic fields | |
US20070197953A1 (en) | Magnetic particles for therapeutic treatment | |
Peyer et al. | Magnetic polymer composite artificial bacterial flagella | |
US20230088973A1 (en) | Propeller and method in which a propeller is set into motion | |
Subramanian et al. | Remote manipulation of magnetic nanoparticles using magnetic field gradient to promote cancer cell death | |
Huang et al. | Optimization of tail geometry for the propulsion of soft microrobots | |
CN101983172A (en) | Unipolar magnetic carrier for 3d tumor targeting | |
EP3618815B1 (en) | Propulsion and control of a micro-device | |
Schürle et al. | Holonomic 5-DOF magnetic control of 1D nanostructures | |
Joshi et al. | Heat generation from magnetic fluids under alternating current magnetic field or induction coil for hyperthermia-based cancer therapy: Basic principle | |
Martel et al. | Computer 3D controlled bacterial transports and aggregations of microbial adhered nano-components | |
Lampropoulos et al. | Computational study of the particles interaction distance under the in uence of steady magnetic field | |
JP2008546677A (en) | How to prepare magnetized particles in a place | |
Temel et al. | Navigation of mini swimmers in channel networks with magnetic fields | |
Ramos-Sebastian et al. | Multimodal locomotion of magnetic droplet robots using orthogonal pairs of coils | |
Asmatulu et al. | Targeting magnetic nanoparticles in high magnetic fields for drug delivery purposes | |
JP2021531076A (en) | Magnetic propulsion mechanism for magnetic devices | |
Yu et al. | Oscillating magnetic field enhanced Janus particle swimming in shear flow | |
Gage | Design of an Electromagnetic Assembly for Active Transport of Microparticles | |
Böyük | Designing a system to manipulate micro magnetic beads and cells | |
Laha et al. | Dynamics and biomedical application of novel superparamagnetic helical nanorobots | |
Ablay et al. | A horizontal magnetic tweezer for single molecule micromanipulations |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
PB01 | Publication | ||
PB01 | Publication | ||
SE01 | Entry into force of request for substantive examination | ||
SE01 | Entry into force of request for substantive examination | ||
GR01 | Patent grant | ||
GR01 | Patent grant |